Your search keyword '"mechanical regeneration"' showing total 3 results

1. The influence of biomaterial in the binder composition on the quality of reclaim from furan no-bake sands

Author

Katarzyna Major-Gabryś, Małgorzata Hosadyna-Kondracka, Mateusz Skrzyński, and Iwona Stachurek

Subjects

biodegradability, biomaterial (pcl), mechanical regeneration, organic moulding sand, post-regeneration dust, waste disposal, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The aim of this paper is to determine the influence of biomaterial in the binder composition on the quality of reclaim from furan no-bake sands. The biomaterial is introduced into the moulding sand in order to accelerate the biodegradation of post-regeneration dust and thus to reduce the amount of harmful waste from foundries in landfills. This addition, however, can’t deteriorate the technological properties of the moulding sand, including its ability to mechanical regeneration. Chemically bonded moulding sands are characterized by high ability to mechanical regeneration, which reduces the consumption of the raw material and costs related to their transport and storage. A side effect of the regeneration process is the formation of a large amount of post-regeneration dusts. According to the tendencies observed in recent years, moulding processes must meet high requirements connected to environmental protection including problems related to the disposal of generated wastes. A partial replacement of synthetic binding materials with biomaterials may be one of scientific research directions on the production of innovative foundry moulding and core sands. The conducted regeneration tests presented in this paper initially proved that biomaterial slightly decreases the quality of reclaim from moulding sand with its addition. However, its ability to regeneration increases with time of the process. In previous research authors tested biodegradability of the dust remaining after the regeneration process. The tests proved that moulding sand with biomaterial added at the stage of the production process is characterized by about three times better biodegradability than the same moulding sand without additive.

Published

2022

2. The influence of biomaterial in the binder composition on the quality of reclaim from furan no-bake sands.

Author

Major-Gabrys, Katarzyna, Hosadyna-Kondracka, Małgorzata, Skrzynski, Mateusz, and Stachurek, Iwona

Subjects

*BIOMATERIALS, *FURANS, *BINDING agents, *BIODEGRADATION, *RAW materials

Abstract

The aim of this paper is to determine the influence of biomaterial in the binder composition on the quality of reclaim from furan no-bake sands. The biomaterial is introduced into the moulding sand in order to accelerate the biodegradation of post-regeneration dust and thus to reduce the amount of harmful waste from foundries in landfills. This addition, however, can't deteriorate the technological properties of the moulding sand, including its ability to mechanical regeneration. Chemically bonded moulding sands are characterized by high ability to mechanical regeneration, which reduces the consumption of the raw material and costs related to their transport and storage. A side effect of the regeneration process is the formation of a large amount of post-regeneration dusts. According to the tendencies observed in recent years, moulding processes must meet high requirements connected to environmental protection including problems related to the disposal of generated wastes. A partial replacement of synthetic binding materials with biomaterials may be one of scientific research directions on the production of innovative foundry moulding and core sands. The conducted regeneration tests presented in this paper initially proved that biomaterial slightly decreases the quality of reclaim from moulding sand with its addition. However, its ability to regeneration increases with time of the process. In previous research authors tested biodegradability of the dust remaining after the regeneration process. The tests proved that moulding sand with biomaterial added at the stage of the production process is characterized by about three times better biodegradability than the same moulding sand without additive. [ABSTRACT FROM AUTHOR]

Published

2022

3. Use of a swirling flow to mechanically regenerate catalysts after methane decomposition.

Author

Hatanaka, Takeshi and Yoda, Yukihiro

Abstract

A new device is proposed to regenerate catalysts after hydrogen production via methane decomposition. Because carbon deposition inhibits catalytic reactions, carbon removal is indispensable for continuous hydrogen production. This device generated a swirling flow by gas supplied at the top and bottom along the inner surface of a tube. The swirling flow rotated the catalyst particles in the tube. Shear stresses on the particles caused by inter-particle and particle-wall impacts led to attrition. Carbon was mechanically removed from the particles by attrition and was elutriated with the flue gas. Ten cycles of methane decomposition and catalyst regeneration were performed using reduced ilmenite as a catalyst. Carbon was clearly removed by catalyst regeneration. Stable regeneration was confirmed by examination of weight changes of the particles caused by carbon deposition and removal during the cycles. Hydrogen production increased by 10% during the cycles than during continuous methane decomposition for 4 h. [Display omitted] • A new regeneration device is proposed for catalytic methane decomposition. • Mechanical regeneration via shear stresses was used to remove carbon. • Ten cycles of decomposition and regeneration were successfully carried out. • Greater hydrogen production was confirmed by catalyst regeneration. [ABSTRACT FROM AUTHOR]

Published

2022